EP0064736A1 - Light pick-up device - Google Patents

Abstract

The invention relates to a light-receiving device for viewing and / or monitoring scanning in drum or flat bed scanning devices. The light receiving device (11) consists of a hollow body which has a light entry opening (16), a light passage opening (17) and at least one opening forming the light receiving surface (13). The part of the inner surface opposite the light receiving surface (13) is designed as a diffuse reflector (20) and the remaining part as a mirror (21). The scanning light coming from the original is collected in the light receiving device (11), reflected in the light receiving surface (13) and from there to an optoelectronic transducer device (15) which generates the image signal. With the light receiving device (11) a high efficiency and a good uniformity of the scanning is achieved, since in particular the disturbing influence of scratches and shadow edges in the original is suppressed.

Description

Technical field

The invention relates to a light-receiving device of an optoelectronic scanning element for review and supervision templates in flatbed or drum scanning devices.

State of the art

Flatbed or drum scanners can be found e.g. B. application in facsimile transmission technology. A light beam scans the original to be reproduced point by line and line by line.

The scanning light coming from the original falls on an optoelectronic scanning element and is converted there into an image signal. The image signal is transmitted via a transmission channel to a facsimile recording device in which the reproduction of the original is recorded.

The templates to be reproduced are font-before layered, screened or non-screened picture templates or templates assembled from writing and pictures, so-called adhesive mounting.

In a flatbed scanning device, the optoelectronic scanning element is designed in such a way that its light receiving surface extends at least over the line length, so that in every position of the deflected light beam there is approximately the same recording condition for the scanning light coming from the original.

The optoelectronic scanning element can consist of a series of photodiodes in the form of a photodiode strip which is arranged in the light receiving area. However, the scanning element can also be an optical cross-sectional transducer constructed from a large number of optical fibers and a discrete optoelectronic transducer, e.g. B. have a photo multiplier, the surface of the optical cross-section converter with the larger extension forms the light receiving surface and the discrete optoelectronic converter is coupled to the surface with the smaller extension.

Scratches in the original and so-called shadow edges in adhesive assemblies reflectively diffuse the scanning light with asymmetrical intensity distribution from the original, and scanning errors are the result.

From US Pat. No. 4,080,634 a flat bed scanning device with a scanning element for supervisory originals is already known. In the scanning organ a light recording device is present, which collects the scanning light reflected by the supervisory original and reduces it to a photodiode strip in order to reduce the above-mentioned scanning errors.

The known light recording device, which extends over the line length, has on the side facing away from the original and on the side facing the original in each case a light opening oriented in the line direction for the deflected light beam or for the reflected scanning light. The interior of the light receiving device is mirrored and has an elliptical cross section perpendicular to the line direction. The light receiving device is arranged so that the one focal point of the ellipse coincides with the point of incidence of the light beam on the original. The scanning light of the original is reflected by the reflecting inner surface in the other focal point of the ellipse, in which the light receiving surface of the photodiode strip is located.

This known light recording device has the disadvantage that such a photodiode strip is relatively insensitive and slow, which means that only a low scanning speed can be achieved. A higher scanning speed could be achieved, for example, by using faster photo multipliers. The arrangement of a large number of photo multipliers instead of the photodiode strip would be complex in the known light receiving device and hardly possible for reasons of space requirements. The arrangement of an optical cross-section converter instead of The photodiode strip would have considerable disadvantages in the known light receiving device. Since the angle at which an optical fiber of the optical cross-sectional converter can take up light is substantially smaller than the angle at which a photodiode strip can take up light, only a small part of the reflecting inner surface would be effective in the known light receiving device, which increases sensitivity and Sampling uniformity decrease.

A further disadvantage is that the known light-receiving device is only suitable for scanning supervisory originals in flatbed scanning devices, but not for see-through originals and for drum scanning devices.

Disclosure of the invention

It is therefore an object of the present invention to provide a light-receiving device for see-through and / or top-view scanning to avoid the disadvantages mentioned, with which a high scanning speed and at the same time a high sensitivity and uniformity of the scanning are achieved and which are suitable both for drum and is also suitable for flatbed scanning devices.

This object is achieved by the features specified in claims 1 and 2.

Advantageous further developments are specified in the subclaims.

Brief description of the drawings

• Figur 1 ein Ausführungsbeispiel einer Lichtaufnahme-Vorrichtung bei einer Flachbett-Abtasteinrichtung für Aufsichts-Vorlagen;
• Figur 2 ein Schnittbild der Lichtaufnahme-Vorrichtung für Aufsichts-Vorlagen; .
• Figur 3 ein weiteres Ausführungsbeispiel einer Lichtaufnahme-Vorrichtung bei einer Flachbett-Abtasteinrichtung für Durchsichts-Vorlagen;
• Figur 4 ein Schnittbild der Lichtaufnahme-Vorrichtung für Durchsichts-Vorlagen;
• Figur 5 ein Ausführungsbeispiel einer Lichtaufnahme-Vorrichtung bei einer Trommel-Abtasteinrichtung für Durchsichts-Vorlagen;
• Figur 6 eine Ausgestaltung der Lichtaufnahme-Vorrichtungen für Farb-Abtasteinrichtungen;
• Figur 7 eine weitere Ausgestaltung.

The invention is explained in more detail below with reference to FIGS. 1-7. Show it:

• Figure 1 shows an embodiment of a light receiving device in a flatbed scanner for supervisory originals;
• Figure 2 is a sectional view of the light receiving device for supervisory originals; .
• FIG. 3 shows a further exemplary embodiment of a light receiving device in a flat bed scanning device for see-through originals;
• Figure 4 is a sectional view of the light receiving device for transparency originals;
• FIG. 5 shows an exemplary embodiment of a light receiving device in a drum scanner for transparent originals;
• FIG. 6 shows an embodiment of the light-receiving devices for color scanning devices;
• Figure 7 shows a further embodiment.

Best way to carry out the invention

Figure 1 shows an embodiment of a light Recording device in a flatbed scanner for supervisory documents.

On a movable flatbed template carrier 1 is a supervisory template to be reproduced 2. A light source 3, z. B. a laser light generator, generates a light beam 4, which falls on a multi-surface rotating mirror 5. The axis of rotation 6 of the multi-surface rotating mirror 5 is aligned perpendicular to the optical axis of the light beam 4. A motor 7 drives the multi-surface rotating mirror 5 at a constant angular velocity in the direction of an arrow 8. Due to the rotation of the multi-surface rotating mirror 5, the light beam 4 emanating from the light source 3 is reflected by the individual mirror surfaces and continuously deflected by a lens 9 in the line direction 10 (scanning direction) via the supervisory template 2. At the same time, the flat-bed original carrier 1 executes a step-by-step or continuous feed movement perpendicular to the line direction 10, as a result of which the supervisory original 2 is scanned point by point in adjacent lines.

A stationary light-receiving device 11 is arranged above the movable flat-bed original carrier 1 and extends in the row direction 10 at least over the length of the flat-bed scanning carrier 1. The light receiving device 11 is designed as a hollow body, the inner surface of which reflects. Approximately perpendicular to the deflection plane of the light beam 4 'reflected by the multi-surface rotating mirror 5, the light receiving device 11 has an orientation in the line direction 10 slit-shaped light opening, which in the exemplary embodiment is filled by that surface of an optical cross-section converter 12 which has the greater extent and forms the light-receiving surface 13 of the light-receiving device 11. The optical cross-sectional converter 12 is constructed from a large number of optical fibers. The surface 14 of the optical cross-sectional transducer 12 with the smaller dimension is connected to an optoelectronic transducer 15, e.g. B. coupled to a photo multiplier. The light receiving device 11 furthermore has a slit-shaped light entry opening 16 oriented in the line direction 10 on the side facing away from the supervisory template 2 and a further slit-shaped light passage opening 17 on the side facing the supervisory template 2, through which the scanning Beam of light 4 'reaches the supervisory template 2. The scanning light modulated with the image content of the supervisory template 2 falls through the light passage opening 17 into the light receiving device 11, is reflected from the inner surface thereof into the light receiving surface 13, transported through the optical cross-sectional converter 12 to the optoelectronic converter 15 and there into an image signal converted on a line 18. The exact beam path, indicated only schematically by an arrow in FIG. 1, is explained in detail in FIG. 2.

FIG. 2 shows a sectional view through the light-receiving device 11 perpendicular to the line direction 10 along the line 19 indicated by dashed lines in FIG. 1.

The light entry opening 16, the light passage opening 17 as well as an optical fiber 12 'and its sheathing 12 "of the optical cross-sectional converter 12 are visible in the sectional view. The light receiving surface 13 is formed by the end face of the optical fiber 12' which defines the optical axis 12 ^* and has the opening angle, only at the opening angle β light hitting the end face is passed through the optical fiber.

On the side of the light-receiving device 11 opposite the light-receiving surface 13, the inner surface is designed as a diffuse reflector 20, at least in the region which is limited by the opening angle β of the optical fiber 12 ', while the remaining inner surface is made of reflecting reflectors (mirrors) 21 and 21 'exist. Alternatively, the entire inner surface could be diffusely reflective.

The shape and spacing of the reflector 20 are selected so that as large as possible a large proportion of the light diffusely reflected by it falls on the light receiving surface 13 within the opening angle β. The diffuse light coming from the reflector 20, which does not directly hit the light receiving surface 13, is guided back to the reflector 20 by the mirrors 21 and 21 'with almost no loss and is again diffusely reflected.

Light-receiving surface 13 and light passage opening 17 are to each other such that neither of the _A ufsichts template 2 coming scanning light directly into the light receiving surface 13, but is diffusely reflected at least once on the reflector 20.

The light entry opening 16 is expediently chosen to be so large that the unmodulated scanning light reflected from a glossy original surface emerges directly from the light entry surface 16 and is not taken into account.

The distance between the light passage opening 17 and the supervisory template 2 and the size of the light passage opening 17 are expediently chosen as follows.

In the case of image originals, the distance is small, as a result of which as much scanning light as possible enters the light receiving device 11 from all reflection directions of the supervisory original 2. The size of the light passage opening 17 is also small, so that the disruptive influence of the supervisory template 2, which is itself involved in the reflections within the light receiving device 11 in the area of the light passage opening 17, is small.

In the case of line templates and adhesive assemblies, on the other hand, the distance is chosen to be larger, so that, in particular, the thicker adhesive assemblies can pass through the narrow gap between the light receiving device 11 and the supervisory template 2 unhindered. The size of the light passage opening 17 is chosen to be correspondingly larger, so that even with the greater distance, as much scanning light as possible from all reflection directions of the supervisory template 2 can get into the light receiving device 11.

For further explanation, some characteristic beam paths are shown in FIG.

The scanning light beam 4 'passes through the light entry port 16 and the light passage opening 17 mounted on the on the flat bed pre la ^g enträger 1 supervisory template 2. The light beam 4' is on the supervisory original 2 on the image content of the momentary scanning point 22 modulated and diffusely thrown back from the scanning point 22 as a scanning light bundle 23 diverging with the opening angle γ ₁ through the light passage opening 17 into the light receiving device 11. The marginal ray 24 of the scanning light bundle 23 strikes the reflector 20 and is resolved in scattered light 25 with the intensity distribution shown (intensity = length of the arrows), from which the scattering light bundle 26 diverging with the angle α strikes the light receiving surface 13 . The marginal ray 27 of the scanning light bundle 23 does not fall on the light receiving surface 13, but is directed by the mirrors 21 onto the reflector 20 and also resolved into scattered light 28, from which the diverging scattered light bundle 29 is reflected directly onto the light receiving surface 13. The scattered light that does not fall on the light receiving surface 13 strikes the reflector 20 directly or via the mirrors 21 and 21 ′, for example, the scattered beam 30 falls directly on the reflector 20, while the scattered beam 31 hits the reflector 20 via the mirror 21 and resolved again in stray light 32. from which the scattered light bundle 33 in turn falls onto the light receiving surface 13.

The part of the scanning light bundle 23, which originates from mirror reflection on the supervisory template 2, is reflected with the smaller opening angle γ ₂ , leaves the light receiving device 11 through the light entry opening 16 and is ineffective.

If the scattered light bundles striking the light receiving surface 13 coincide with the main directions of the scattered light (scattered light with the greatest intensity), there is an optimal efficiency of the light receiving device 11. This is the case when the reflector 20 and the mirror 21 'Are part of a circle, the center of which is the base point of the surface normal 12 ^* (optical axis) of the light receiving surface 13 and if the mirrors 21 are part of a second circle of the same size, the center of which is the intersection of the optical axis 12 ^* with the reflector 20. In the exemplary embodiment, a circular cross section is assumed for the sake of simplicity.

The light receiving device 11 according to the invention has the following advantages. The described arrangement of reflector 20 and mirrors 21 and 21 'causes a large proportion of the scanning light reflected by the supervisory template 2 to reach the light-receiving surface 13 and, via the cross-sectional converter 12, to the optoelectronic converter 15. The light-receiving device 11 thus has one high efficiency, so that the scanning light beam 4 generating light source 3 can have a lower power.

Due to the large proportion of scanning light that reaches the optoelectronic converter and the diffuse reflection on the reflector 20, the full opening angle β of the optical fiber 12 'is used and the disruptive influence of scratches and shadow edges in the original is suppressed, thereby achieving a high reproduction quality becomes.

Since the scattered light emanating from the reflector 20 also spreads in the longitudinal extent of the light receiving surface 13, a large number of optical fibers are involved in the light transport to the optoelectronic converter, which advantageously eliminates the uneven transmission property of the individual optical fibers and achieves a high uniformity of the scanning .

FIG. 3 shows a further exemplary embodiment of a light receiving device in a flat bed scanning device for see-through originals.

There is a see-through template 2 'on the movable and transparent flat bed scanning carrier 1'. Arranged under the flat bed scanning carrier 1 'is a stationary light receiving device 11a which is modified compared to the embodiment shown in FIG. 1 and also extends at least over the length of the flat bed scanning carrier 1' in the line direction 10. The modified light receiving device Tung Ila only has a slit-shaped light entry opening 16a on the side facing the see-through template 2 '. The light beam 4 'is deflected by the multi-surface rotating mirror 5 point by line and line by line through the see-through template 2', and the scanning light falls through the transparent flat bed original carrier 1 'and the light entry opening. 16a into the light receiving device lla. The scanning light is in turn reflected from the inner surface of the light receiving device 11a onto the light receiving surface 13, transported through the optical cross-sectional converter 12 to the optoelectronic converter 15 and converted there into an image signal.

In the case of original scanning devices for optional supervisory and see-through scanning, the light receiving device can preferably be designed to be displaceable perpendicularly to the flatbed scanning carrier, so that the light receiving device is located above or below the flatbed scanning carrier, depending on the type of original according to FIGS. 1 or 3 is located, the slit-shaped light passage opening 17 of Figure 1 is designed to be closable by suitable means in the case of a transparent scan.

Alternatively, such original scanning devices can each be equipped with a light-receiving device for top-up scanning and one for transparent scanning, which are activated depending on the type of original. The presence of two light recording devices has the advantage in particular in the case of transparent scanning, that both light receiving devices can be optically or electrically connected in parallel for the purpose of eliminating image signal interference due to dust particles, scratches, etc., in the case of an optical parallel connection the light exit surfaces of the optical cross-sectional transducers from both light receiving devices are coupled to an optoelectronic converter, while an electrical one Parallel connection, the outputs of the optoelectronic converters are combined.

FIG. 4 shows the modified light receiving device 11a for see-through scanning in a sectional image.

The modified light-receiving device 11a has a diffuse reflector 20 enlarged by part 20 'compared to the light-receiving device 11.

The scanning light beam 4 'falls on the see-through template 2', is modulated with the image content at the scanning point 22 and arrives as a scanning light bundle 34 diverging with the aperture angle γ ₁ through the light entry opening 16a into the light receiving device 11a. The marginal ray 35 of the scanning light bundle 34 is resolved by the diffuse reflector 20 into scattered light 36, from which the scattered light bundle 37 diverging with the angle α strikes the light receiving surface 13 directly. The scattered beam 38 of the scattered light 36 falls z. B. on the diffuse reflector 20 and is in turn resolved into scattered light 39, of which the Stray light bundle 40 in turn reaches the light receiving surface 13 directly. The scattered beam 41 of the scattered light 36, on the other hand, is reflected by the mirror 21 onto the diffuse reflector 20.

Preferably, a glass plate, a diffusing screen or a lens is arranged in the light entry opening 16a, which protect the interior of the light receiving device 11a from dust. The use of a scattering medium has the additional advantage that the opening angle 1 of the scanning light bundle 34 is increased to the opening angle γ ₂ . As a result, a larger part of the inner surface is involved in the reflections and the light receiving device is less sensitive to dust particles located in the interior. For this purpose, a diverging lens 42 is provided in FIG. 4 in the light entry opening 16a.

It is of course within the scope of the invention to arrange a large number of photodiodes, photo multipliers or other optoelectronic transducers instead of the optical cross-sectional transducer in the light receiving surface 13 itself.

The previously described embodiments of the light-receiving device with the sectional images according to FIGS. 2 or 3 are intended for flat-bed scanning devices and are designed in such a way that they extend at least over the length of the flat-bed scanning carrier, as can be seen from FIGS

Figures 1 and 3 emerges.

The light receiving device can also be used in an advantageous manner with drum scanning devices. In this case, the light receiving device 11b is designed, for example, as a hollow sphere with the cross section according to FIGS. 2 or 4. The light receiving surface 13 is no longer slit-shaped, as shown in FIGS. 1 and 3, but is circular or square. The cross-sectional converter 12 is omitted, and the optoelectronic converter 15 is arranged directly in the light receiving surface 13 or connected via at least one optical fiber.

An exemplary embodiment of a light receiving device in a drum scanner for supervisory originals is given in FIG. 5.

The supervisory template 2 to be reproduced is mounted on a scanning drum 43 which is driven by a motor 44. A light source 45 and the spherical light receiving device 11b move in the same direction in the direction of an arrow 46 past the scanning drum 43. The light beam 4 ′ emanating from the light source 45 falls through the light entry opening 16 and the light passage opening 17 of the light receiving device 11b onto the supervisory template 2. The scanning light is transmitted from the supervisory template 2 through the light passage opening 17 in the light-absorbing device 11b is thrown back and reflected from the inner surfaces onto the light-absorbing surface and from the optoelectronic Converter 15 converted into the image signal.

In the case of drum scanning devices for see-through originals, a spherical light receiving device with the cross section according to FIG. 4 can in turn be arranged inside the scanning drum.

The explanations given for the flatbed scanning devices apply mutatis mutandis to either supervisory or transparent scanning.

The spherical light-receiving device according to FIG. 5 can also advantageously be used with flat-bed scanning devices if the flat-bed scanning carrier is stationary and the light source and light-receiving device move over the flat-bed scanning carrier for point-by-line and line-by-line scanning.

An advantageous embodiment of the light receiving device according to the invention in scanning devices for colored originals is indicated in FIG.

FIG. 6 shows a section of the sectional view of a light-receiving device according to FIGS. 2 or 4. Shown is the light-receiving surface 13 with part of the mirrors 21. At least three optical fibers 47, 48 and 49 are arranged one above the other in the sectional plane, the light entry surfaces of which reflect the light-receiving surface 13 form the light receiving device. In a tubular light receiving device for flat bed scanning, the lights are fibers 47, 48 and 49 z. B. part of the cross-sectional converter, in contrast, in a spherical light receiving device for drum scanning at least three separate optical fibers or optical fiber bundles. For the purpose of color separation of the scanning light, the light exit surfaces of the optical fibers 47, 48 and 49 are coupled via three dichroic filters 50, 51 and 52 to three optoelectronic converters 53, 54 and 55, which transmit the three color measurement signals r, g and b on the lines 56, 57 and 58 deliver.

FIG. 7 shows a further embodiment of the light recording device according to the invention for top-view or see-through scanning in a sectional view.

The light-receiving surface 13 with the opening angle is opposite a second light-receiving surface 13 ^* , which may also have the opening angle β, for example. The inner surfaces opposite each other in the area of the opening angle β are designed as reflectors 20 and the remaining inner surfaces as mirrors 21. Such a light recording device can in turn advantageously be used to eliminate image signal interference due to dust particles, shadow edges or scratches.

In the selected exemplary embodiment, optoelectric converters 15 and 15 ^{* are} coupled to the optical fibers 12 and 12 ^*, respectively. In this case, the converters 15 and 15 ^* are electrically connected in parallel to eliminate the image signal interference. Alternatively, the Optical fibers 12 and 12 ^* optically connected in parallel and coupled to a common converter.

Claims (16)

1. Light recording device for the point-by-line and line-by-line optical-electrical scanning of see-through documents, consisting of an internally reflective hollow body which has a light entry opening on the side facing the see-through document for the scanning light modulated with the image content of the document , wherein the recorded scanning light is reflected by the inner surface of the hollow body on a light receiving surface, characterized in that a) the hollow body (11) has at least one opening forming the light-receiving surface (13), b) the inner surface of the hollow body (11) opposite the light receiving surface (13), at least in an area covered by the opening angle of the light receiving surface (13) as a diffusely reflecting first reflector (20) and the inner surface adjacent to the light receiving surface (13) as a second reflector (21) is formed, wherein c) the reflectors (20, 21) are arranged in relation to one another in such a way that the incident light is directed in each case onto the opposite reflector, d) the first reflector (20) is shaped and aligned with the light receiving surface (13) in such a way that a large proportion of the scattered light is reflected the light receiving surface (13) falls, and e) the light entry opening (16) is designed and aligned with the light receiving surface (13) in such a way that the scanning light does not fall directly onto the light receiving surface (13), but is diffusely reflected at least once by the reflector (20). 2.Light recording device for the point-by-line and line-by-line optical-electrical scanning of supervisory documents, consisting of an internally reflective hollow body which has a light entry opening on the side facing away from the supervisory document for the scanning light beam and on which the supervisor - Template side facing a light passage opening. for the scanning light beam and for the scanning light modulated with the image content of the supervisory template, the recorded scanning light being reflected from the inner surface of the hollow body onto a light receiving surface, characterized in that a) the hollow body (11) has at least one opening forming the light-receiving surface (13), b) the inner surface of the hollow body (11) opposite the light-receiving surface (13) at least in a region covered by the opening angle (β) of the light-receiving surface (13) and struck by the scanning light as a diffusely reflecting first reflector (20) and the surface (13 ) adjacent inner surface is designed as a second reflector (21), wherein c) the reflectors (20; 21) are arranged with respect to one another in such a way that the incident light is directed in each case onto the opposite reflector, d) the first reflector (20) is shaped and aligned with the light receiving surface (13) in such a way that a large proportion of the scattered light falls on the light receiving surface (13), and e) the light passage opening (17) is designed and aligned with the light receiving surface (13) in such a way that the scanning light does not fall directly onto the light receiving surface (13), but is diffusely reflected at least once by the reflector (20). 3. Light receiving device according to claim 1 or 2, characterized in that the second reflector (21) is designed as a diffuse reflector. 4. Light receiving device according to claim 1 or 2, characterized in that the second reflector (21) is designed as a mirror. 5. Light receiving device according to claim 2, characterized in that the light entry opening (16) is chosen so large that the scanning light generated by mirror reflection on the template exits through the light entry opening (16) again from the hollow body (11) . 6. Light receiving device according to one of claims 1 to 5, characterized in that the cross section of the hollow body (11) perpendicular to the light receiving surface (13) is designed as follows, a) the first reflector (20) is part of a first circle, the center of which is the base point of the surface normal (12 *) of the light-receiving surface (13), and b) the second reflector (21) is part of an equally large second circle, the center of which is the intersection of the surface normal (12 *) with the first reflector (20). 7. Light receiving device according to one of claims 1 to 7, characterized in that the hollow body (11) for scanning flat original carriers (flat bed scanning) extends at least over the line length, with openings (16, 17) and light receiving surface ( 13) also extend at least over the line length. 8. Light receiving device according to one of claims 1 to 5, characterized in that the hollow body (11) is designed for scanning flat original carriers as a cylinder. 9. Light receiving device according to claim 8, characterized in that the hollow body (11) is a slotted tube. 10. Light receiving device according to one of claims 1 to 5, characterized in that the hollow body (11) for scanning the drum shaped original carriers (drum scanning) is formed symmetrically to the optical axis of the scanning light beam. 11. Light receiving device according to one of claims 1 to 5, characterized in that the hollow body (11) is designed as a hollow ball. 12. Light receiving device according to one of claims 1 to 11, characterized in that the light receiving surface (13) is formed by an end face of an optical cross-sectional transducer, to the other end face of which an optoelectronic transducer is coupled. 13. Light receiving device according to claim 1, characterized in that the light entry opening (16) is closed with a glass plate. 14. Light receiving device according to claim 1, characterized in that the light entry opening (16) is closed by a scattering medium. 15. Light receiving device according to claim 2, characterized in that the light passage opening (17) for scanning transparent documents is closable. 16. Light recording device for scanning colored originals according to one of claims 1 to 15, characterized in that the of Light receiving surface (13) recorded light is given to at least three dichroic filters.

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